STATUS REPORT ON SPIRAL1 F. Chautard October 2 nd, 2007

STATUS REPORT ON SPIRAL1 F. Chautard October 2 nd, 2007 Assessment of GANIL/SPIRAL operation Technical achievements Present R&D Possible developments

SPIRAL: Radioactive ion beams with «ISOL» method since 2001 Heavy Ion Beams up to 95 MeV/A onto a thick carbon target radioactive atoms Acceleration and Purification in a compact cyclotron CIME Radioactive Isotopes (He, N, O, Ne, Ar, Kr, F) Ionisation by an ECR ion source Post-acceleration by CIME cyclotro PRODUCTION target

Multi-beam operating mode: 4 experiments in parallel High Energy Beam GANIL [24, 95] MeV/A 3 4 4 3 SME : 2 after a stripper, one charged state is sent to the D1 room => the medium energy exit [3.7, 13.7] MeV/A a spectro 2 Stripper 1 IRRSUD : low energy beam irradiation line [0.3, 1.0] MeV/A 1

Multi-beam operating mode: Beam schedule

Running Statistics 2001-2006 Availability: 90% GANIL per year: 35 weeks / 4 periods: 5700h of operating time. Leading to 7200h of beam time for users (multi-beam effect) SPIRAL since 2001: 5000h of exotic beams / 700h of stable beams. More than 30 exotic beams

Primary beams (http://www.ganil.fr/operation/available_beams/available_beams_tabular.htm). Beam Imax [mae] [pps] Emax [MeV/A] Pmax [W] Used with Spiral X 3 000 C 6+ 18 1.9 10 13 95 3 200 13C6+ 18 2. 10 13 80 3 000 14N7+ 15 1.4 10 13 95 16O8+ 16 10 13 95 3 000 X 18O8+ 17 10 13 76 3 000 X 20Ne10+ 17 10 13 95 3 000 X 22Ne10+ 17 10 13 79 3 000 36S16+ 6.4 2.5 10 12 77.5 1100 X 36Ar18+ 16 5.5 10 12 95 3 000 X 40Ar18+ 17 6. 10 12 77 3 000 48Ca19+ 4-5 1.3 10 12 60 600-700 X 58Ni26+ 5 1.2 10 12 77 860 76Ge30+ 5 1.2 10 12 60 760 78-86Kr34+ 7.5 1.4 10 12 70 1200 X 124 Xe46+ 2 2.7 10 11 53 300

ion W [MeV/A] [pps] SPIRAL operation (http://www.ganil.fr/operation/available_beams/radioactive_beams.htm) Year ion W [MeV/A] [pps] Year 18 Ne 7 10 6 2001 31 Ar 1.45 1.5 2004 8 He 15.5 10 4 2001 6 He 3.2, 5 3.10 7 2004 8 He 3.5 10 5 2002 8 He 15.4 2.10 4 2005 24 Ne 4.7 2 10 5 2002 8 He 3.4-3.9 8 10 4 2005 74 Kr 8 He 8 He 24 Ne 8 He 15 O 24 Ne 33 Ar 6 He 8 He 35 Ar 6 He 4.6 15.4 15.4 10 15.4 1.2 7.9 6.5 3.8 15.4 0.428 2.5 1.5 10 4 1.5 10 4 9 10 3 2 10 5 2.5 10 4 1.7 10 7 1.4 10 5 3 10 3 2.8 10 7 2.5 10 4 4 10 7 3.7 10 7 2002 2002 2002 2002 2002 2003 2003 2003 2003 2003 2004 2004 8 He 18 Ne 24 Ne 26 Ne 44 Ar 46 Ar 74 Kr 76 Kr 75 Kr 44 Ar 6 He 6 He 3.5 7 4.7;10 10 10.8 10.3 2.6 2.6-4.4 5.5 3.8 ; 2.6 20 Lirat 6.10 5 10 6 2 10 5 3 10 3 2 10 5 2 10 4 1.5 10 4 6 10 5 2 10 5 3 10 5 5 10 6 2 10 8 2005 2005 2005 2005 2005 2005 2005 2005 2005 2006 2006 2006

Ageing Problems and Maintenance Since few years, the accelerating cavities of the SSC s encountered water leaks due to 25 years of functioning. Interventions require to remove the whole cavity. Inducing one week delay to physics experiment. Corrective actions: Replacement of defective component. Tuning of SSC with one RF cavity.

B sector B Ageing Problems and Maintenance Simulations and analytical calculations show that compensation of a RF acceleration can be done by modifying the magnetic field law. ( r) = ± 0.5 cos(45 ) σ injection r injection / r Correction coils B/B B/B theory DB/B feasible Radius sector Sector coil

Ageing Problems and Maintenance On a Radial probe: Still precession, but 90% transmission

Ageing Problems and Maintenance In-Flight Separation techniques (SISSI) In June 2007, the second solenoid S2 of the SISSI device quenched during current rising and cannot be used since. The reasons of the repetitive quenches are still unknown (ageing, device weakness, neutron effects ) : Short term alternative solutions are studied.

Ageing Problems and Maintenance R2 Rebuncher The clear interest of such a rebuncher is to reduce the beam losses in CSS2 deflector improving the beam stability, (especially heavy ions such as krypton). Unavailable since 2002 because of defective RF contactors. The cavity is repaired and has been put back in line in 2007. R2

SPIRAL Facility The SPIRAL strengths can be resumed by: Large Energy range of post-accelerator : from 1.2 MeV/A to 16 MeV/A (for Q/A=0.25) Mass purification of the cyclotron R= few 10-4. Good energy definition of the CIME beams E/E < 5 10-3 Good transmission for such an accelerator technology 20%-40%. Great target-source selectivity + cyclotron purification giving a pure beam of most of available ion beams. 40 isotopes available. Possibility to run detectors developments with stable beam of CIME in a stand alone operation.

SPIRAL Facility But SPIRAL has also its limitations: Still, too few radioactive ion species are available (He, O, N, Ne, Ar, Kr, F). Intensity is a parameter of utmost importance; It is the main limitation for most of experiments. The large turn number in CIME impacts the beam emittance: TFWHM < 2ns and emittance ~ 16π.mm.mrd imply multi-turn extraction.

What about improvements since 2001?

2004 Modification of the high voltage platform C01 (100 kvolts) Goal: Increase the beam intensity of the source Limitation: space charge Solution: Increase the extraction voltage from 25 kv to 100 kv in two stages. First stage: extraction at 25 kv and selection to remove unwanted intense beams Second stage: acceleration to the wanted energy for injection into the C0 => Beam more stable, gain of a factor 1.5-2 in intensity (S, Kr, Mg, Ar) 36 S 8+ 38 mae 78 Kr 15+ 30 mae

SPIRAL Working diagram extension

Tuning optimization 1600 1400 1200 hours 1000 800 600 400 200 0 21% 24% 15% 7% 7% 2002 2003 2004 2005 2006 years SPIRAL beams SPIRAL tuning

Irradiation control of Spiral Target Until few days ago the irradiation time was limited to 15 days due to safety regulation (worst computed figure for target activation). The goal is to be more precise in the criteria of limitation: ion species, intensity, energies. This will be achieved by controlling the ion integrated flow over the lifetime of the target. Solution: use of a Current Transformer coupled to an automatic beam stop and data storage. GAIN: Decreases the volume of the nuclear waste. Optimises the device availability. Decreases the frequency of the handling operations and manpower.

And from now?

Development of a 1+/N+ radioactive alkali ion source Isotopes Krypton 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 Argon 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 Neon 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 Fluorine 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 Oxygen 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 Nitrogen 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Helium 3 4 5 6 7 8 9 10 Stable Exotic Physicists demands Radioactive 1+ alkali production tests with IS source (in 2006) Radioactive n+ alkali production tests coupling IS and ECR source (may 2007, very low efficiency 0,04%) Constraints of the production cave (compact solution)

Extension for a Low Energy beam line for radioactive beam An experimental area of 220 m 2 : 3 lines u 1 beam line for long-term experiments u 1 beam line for short-term experiments u 1 beam line for technical developments LIRAT A dedicated and separate acquisition room All SPIRAL beams, including new ones

SPIRAL improvement projects Direct line CIME-experimental caves: Since 2004 Direct beam line between CIME and G1/G2 allowing the transport of ions into experimental rooms in parallel to SSC2 beams.

Status Summary SPIRALTarget-Source developments: Alkali ions: compact solution to be validated in April 2008 for stable ions Metallic ions: stand by Low energy line extension: Predesign study achieved Project under discussion Direct line CIME-experimental caves: Predesign study achieved Under discussion in the frame of the SPIRAL2 project

GANIL-SPIRAL Looking Toward the Future A new machine, SPIRAL2, is about to be constructed on the GANIL site (talk TUZCR04 by P. Bertrand). The post-acceleration of the exotic beams produced will be done by the actual cyclotron CIME from SPIRAL1. Therefore, new safety requirements have to be applied and constraints taken into account for those exotic beams accelerated. In this frame, projects were launched such as access control upgrade, improvement of the SPIRAL1 equipment reliability, new transfer line, Internal report compiles about 15 potential SPIRAL improvements identified before SPIRAL2 coming

Thank you for your attention

Beam dynamics in cyclotron Two RF cavities : Br Cyclotron orbit Smooth H=2 oscillations r Br r RF1 RF2 RF1 RF1 RF1 Cyclotron orbit q q 1 RF cavity (1 OFF) : STRONG H=1 oscillations Simulation in CSS1 radial oscillation : up to 7cm Experime ntally Impossibility to extract the beam 0% transmission!!!!!

Field Corrections (P-Pref)/Pref Pref=Pinj+ q/2p * (DP) RF - s ( p/p0)cavité RF Cavity +DB OFF DB +DB -DB RF Cavity sinjection=turn separation At injection RF1 RF2(OFF) RF1 + B + B - B - B B C D A DB A (R)/B= - 0.5 cos(45 ) sinjection R injection / R 2 DB B (R)/B=+ 0.5 cos(45 ) sinjection R injection / R 2 DB C (R)/B=+ 0.5 cos(45 ) sinjection R injection / R 2 DB D (R)/B=- 0.5 s cos(45 ) σinjection R injection / R 2

Beam dynamics : 0 0 2 ) ( 1 ) ) ( 1 ( '' p p p s x k s x = + 0 ) ( ) ( 1 ) cos( ) ( 2 ) ( 1 ) ) ( 1 ( ' ' 2 = + + B s Bz s s s s x k s x σ σ = = = B B p p cavity 1 Hill equation over 1 turn for the central trajectory With 1 cavity => 1 defect per turn With 1 cavity + field correction => DB (R) /B= - 0.5 σ cos(s/r)/r DB A (R)/B= - 0.5 cos(45 ) sinjection R injection / R 2 DB B (R)/B= + 0.5 cos(45 ) sinjection R injection / R 2 DB C (R)/B= + 0.5 cos(45 ) sinjection R injection / R 2 DB D (R)/B= - 0.5 s cos(45 ) σinjection R injection / R 2 Reduction of the h=1 oscillation : ) cos( 2 ) ( 1 ) ) ( 1 ( '' 2 σ s s x k s x + Correction of the sectors * sinjection=turn separation at injection